Radiation detector and method for manufacturing radiation detector

ABSTRACT

A radiation detector includes a photoelectric conversion element array, a scintillator layer converting radiation into light, a resin frame formed on the photoelectric conversion element array, and a protective film covering the scintillator layer. The resin frame has a groove continuous with an outer edge of the protective film. The groove includes a pre-irradiation portion formed by performing scanning along the resin frame while increasing the energy of a laser beam, a main irradiation portion formed by performing scanning along the resin frame while maintaining the energy of the laser beam, and a post-irradiation portion formed by performing scanning along the resin frame while decreasing the energy of the laser beam.

TECHNICAL FIELD

The present invention relates to a radiation detector and a method for manufacturing a radiation detector.

BACKGROUND ART

Radiation detectors are disclosed in Patent Literature 1, Patent Literature 2, and Patent Literature 3. Each of the radiation detectors disclosed in Patent Literature 1, Patent Literature 2, and Patent Literature 3 has a scintillator layer converting radiation into light and a photodetection panel detecting light. The photodetector panel has a light receiving portion where a plurality of light receiving elements are disposed and a plurality of bonding pads provided around the light receiving portion and electrically connected to the light receiving portion. A resin frame surrounding the light receiving portion is formed between the light receiving portion and the bonding pad. The scintillator layer is covered with a moisture-resistant protective film.

CITATION LIST Patent Literature

Patent Literature 1: Japanese Unexamined Patent Publication No. 2015-96823

Patent Literature 2: Japanese Unexamined Patent Publication No. 2016-205916

Patent Literature 3: U.S. Patent No. 2012/0288688

SUMMARY OF INVENTION Technical Problem

In the method for manufacturing the radiation detectors disclosed in Patent Literature 1 and Patent Literature 2, the resin frame is formed after the scintillator layer is formed on the photodetection panel. The protective film is formed next. The protective film is formed on the scintillator layer and the bonding pad. The protective film may cover the scintillator layer. In this regard, the protective film covering the bonding pad is removed in part. Specifically, the protective film on the resin frame is cut by irradiation with a laser beam so that the protective film is cut. In other words, the protective film and the resin frame are irradiated bodies on which laser beam irradiation is performed.

The mode of laser beam irradiation may have a slight difference between preset content and actual operation. Then, unintended resin frame cutting may occur in the actual operation even in the case of setting for cutting the protective film without cutting the resin frame.

In this regard, an object of the present invention is to provide a radiation detector and a radiation detector manufacturing method suppressing the occurrence of unintended cutting of an irradiated object.

Solution to Problem

A radiation detector according to one embodiment of the present invention includes: a photodetection panel having a light receiving portion including a plurality of photoelectric conversion elements arranged one-dimensionally or two-dimensionally and a plurality of bonding pads electrically connected to the photoelectric conversion elements and disposed outside the light receiving portion; a scintillator layer laminated on the photodetection panel so as to cover the light receiving portion and converting radiation into light; a panel protection portion formed on the photodetection panel so as to pass between the scintillator layer and the bonding pad and surround the scintillator layer apart from the scintillator layer and the bonding pad when viewed in a lamination direction of the scintillator layer; and a scintillator protective film covering the scintillator layer and having an outer edge positioned on the panel protection portion. A groove continuous with the outer edge of the scintillator protective film is formed in the panel protection portion. The groove includes: a pre-irradiation portion formed by performing scanning along the panel protection portion while increasing energy of a laser beam to a value larger than threshold energy from a value smaller than the threshold energy at which the scintillator protective film can be cut; a main irradiation portion formed by performing scanning along the panel protection portion while maintaining the energy of the laser beam at a value larger than the threshold energy; and a post-irradiation portion formed by performing scanning along the panel protection portion while decreasing the energy of the laser beam from a value larger than the threshold energy to a value smaller than the threshold energy.

The groove of the panel protection portion of the radiation detector is continuous with the outer edge of the scintillator protective film. Accordingly, the groove is formed as the outer edge of the scintillator protective film is formed by laser beam irradiation. When the groove is formed in the panel protection portion, the scintillator protective film formed on the panel protection portion is cut in a reliable manner. In the pre-irradiation portion, irradiation is started from the energy smaller than the threshold energy. According to such an irradiation mode, laser beam irradiation can be started with a margin with respect to the energy required for cutting the panel protection portion. Accordingly, even if energy exceeding a set value is supplied due to an unintended factor at the initiation of the laser beam irradiation, cutting of the panel protection portion can be suppressed by the ensured margin. Likewise, in the post-irradiation portion, irradiation is stopped after the energy is decreased to the energy smaller than the threshold energy. According to such an irradiation mode, laser beam irradiation can be stopped with a margin with respect to the energy required for cutting the panel protection portion. Accordingly, even if energy exceeding a set value is supplied due to an unintended factor when the laser beam irradiation is stopped, cutting of the panel protection portion can be suppressed by the ensured margin. Accordingly, the occurrence of unintended cutting of the panel protection portion as an irradiated object can be suppressed.

The radiation detector may further include a coating resin covering the outer edge of the scintillator protective film. According to this configuration, the occurrence of peeling of the scintillator protective film can be suppressed.

The coating resin of the radiation detector may further cover the panel protection portion. The coating resin may have a material property allowing the coating resin to stay on the panel protection portion such that an edge portion of a contact surface between the coating resin and the panel protection portion is formed on the panel protection portion. According to this configuration, the coating resin reaches neither the surface of the photodetection panel positioned outside the panel protection portion nor the bonding pad. Accordingly, each of the surface of the photodetection panel and the bonding pad can be kept clean.

In the radiation detector, a middle portion of the panel protection portion may be higher than both edge portions of the panel protection portion. According to this configuration, the coating resin is capable of covering the outer edge of the scintillator protective film in a reliable manner.

In the radiation detector, a width of the panel protection portion may be 700 μm or more to 1000 μm or less. According to this configuration, the radiation detector can be reduced in size.

In the radiation detector, a height of the panel protection portion may be 100 μm or more to 300 μm or less. According to this configuration, the radiation detector can be reduced in size.

A radiation detector manufacturing method according to another embodiment of the present invention includes: a step of preparing a photodetection panel having a light receiving portion including a plurality of photoelectric conversion elements arranged one-dimensionally or two-dimensionally and a plurality of bonding pads electrically connected to the photoelectric conversion elements and disposed outside the light receiving portion and laminating a scintillator layer converting radiation into light on the photodetection panel so as to cover the light receiving portion; a step of disposing a panel protection portion on the photodetection panel so as to surround the scintillator layer when viewed in a lamination direction of the scintillator layer; a step of forming a scintillator protective film so as to cover an entire surface of the photodetection panel on a side where the scintillator layer is laminated and a surface of the panel protection portion; a step of cutting the scintillator protective film by performing irradiation with a laser beam along the panel protection portion; and a step of removing an outside part of the scintillator protective film. The step of cutting the scintillator protective film includes: a pre-irradiation step of performing scanning along the panel protection portion while increasing energy of the laser beam to a value larger than threshold energy from a value smaller than the threshold energy at which the scintillator protective film can be cut; a main irradiation step of performing scanning along the panel protection portion while maintaining the energy of the laser beam at a value larger than the threshold energy; and a post-irradiation step of performing scanning along the panel protection portion while decreasing the energy of the laser beam from a value larger than the threshold energy to a value smaller than the threshold energy.

In the radiation detector manufacturing method, the outer edge of the scintillator protective film and the groove of the panel protection portion are formed in the step of cutting the scintillator protective film. When the groove is formed in the panel protection portion, the scintillator protective film formed on the panel protection portion is cut in a reliable manner. Further, the groove is formed as a result of the pre-irradiation step of forming the groove while increasing the energy and the post-irradiation step of forming the groove while decreasing the energy. According to these steps, the depth of the groove does not excessively increase. Accordingly, the occurrence of unintended cutting of the panel protection portion as an irradiated object can be suppressed.

In the radiation detector manufacturing method according to another embodiment, the panel protection portion may include a resin frame. In the step of disposing the panel protection portion, the resin frame may be disposed on the photodetection panel so as to pass between the scintillator layer and the bonding pad and surround the scintillator layer apart from the scintillator layer and the bonding pad. According to this step, a radiation detector having the resin frame can be manufactured.

In the radiation detector manufacturing method according to another embodiment, the panel protection portion may further include a masking member. In the step of disposing the panel protection portion, the masking member may be further disposed on the photodetection panel so as to cover the bonding pad. According to this step, the bonding pad can be suitably protected.

In the radiation detector manufacturing method according to another embodiment, the panel protection portion may include a masking member. In the step of disposing the panel protection portion, the masking member may be disposed on the photodetection panel so as to cover a region between the scintillator layer and the bonding pad and the bonding pad. In the step of forming the scintillator protective film, the scintillator protective film may be formed on the entire surface of the photodetection panel on the side where the scintillator layer is laminated and a surface of the masking member. According to this step, a radiation detector without the resin frame can be manufactured. In other words, the distance between the scintillator layer and the bonding pad can be reduced. As a result, the radiation detector can be further reduced in size.

The radiation detector manufacturing method according to another embodiment may further include a step of removing the masking member after the step of cutting the scintillator protective film. According to this step, the radiation detector without the resin frame can be manufactured in a suitable manner.

The radiation detector manufacturing method according to another embodiment may further include a step of forming a coating resin covering an outer edge of the scintillator protective film after the step of removing the outside part of the scintillator protective film. According to this step, the occurrence of peeling of the outer edge of the scintillator protective film can be further suppressed.

Advantageous Effects of Invention

According to the present invention, a radiation detector and a radiation detector manufacturing method suppressing the occurrence of unintended cutting of an irradiated object are provided.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a plan view of a radiation detector of a first embodiment.

FIG. 2 is a cross-sectional view taken along line II-II of FIG. 1 .

FIG. 3 is an enlarged plan view illustrating the vicinity of a corner portion of the radiation detector of FIG. 1 .

FIG. 4(a) is a cross-sectional view illustrating a state where a scintillator layer is yet to be formed. FIG. 4(b) is a cross-sectional view illustrating a state where the scintillator layer is formed.

FIG. 5(a) is a cross-sectional view illustrating a state where a resin frame is formed. FIG. 5(b) is a cross-sectional view illustrating a state where a first organic film is formed.

FIG. 6(a) is a cross-sectional view illustrating a state where an inorganic film is formed. FIG. 6(b) is a cross-sectional view illustrating a state where a second organic film is formed.

FIG. 7 is a cross-sectional view illustrating laser beam processing.

FIG. 8 is a graph schematically showing a time history of energy received by an irradiated body.

FIG. 9(a) is a cross-sectional view illustrating a pre-irradiation portion. FIG. 9(b) is a cross-sectional view illustrating the pre-irradiation portion and a main irradiation portion. FIG. 9(c) is a cross-sectional view illustrating the pre-irradiation portion, the main irradiation portion, and a post-irradiation portion.

FIG. 10(a) is a cross-sectional view for describing a step of forming the post-irradiation portion. FIG. 10(b) is a cross-sectional view for describing a step of forming the post-irradiation portion following FIG. 10(a).

FIG. 11(a) is a graph showing an example of a time history of the speed of a laser beam head. FIG. 11(b) is a graph showing an example of a time history of the energy of a laser beam emitted from the laser beam head. FIG. 11(c) is a graph showing an example of a time history of the focal position of the laser beam emitted from the laser beam head.

FIG. 12(a) is a graph showing an example of the time history of the speed of the laser beam head. FIG. 12(b) is a diagram schematically illustrating the positional relationship between the laser beam head and a protective film and the resin frame.

FIG. 13(a) is a cross-sectional view illustrating a state where a part of the protective film is removed. FIG. 13(b) is a cross-sectional view illustrating a state where a coating resin is formed.

FIG. 14(a) is a graph schematically showing the time history of the energy received by the irradiated body. FIG. 14(b) is a graph schematically showing the time history of the speed of the laser beam head.

FIG. 15 is a plan view of a radiation detector of a second embodiment.

FIG. 16 is a cross-sectional view taken along line XVI-XVI of FIG. 15 .

FIG. 17 is a first perspective view of the radiation detector of FIG. 15 .

FIG. 18 is a second perspective view of the radiation detector of FIG. 15 .

FIG. 19(a) is a cross-sectional view illustrating a state where a scintillator layer is yet to be formed. FIG. 19(b) is a cross-sectional view illustrating a state where the scintillator layer is formed.

FIG. 20(a) is a cross-sectional view illustrating a state where a masking member is disposed. FIG. 20(b) is a cross-sectional view illustrating a state where the first organic film is formed.

FIG. 21(a) is a cross-sectional view illustrating a state where the inorganic film is formed. FIG. 21(b) is a cross-sectional view illustrating a state where the second organic film is formed.

FIG. 22(a) is a cross-sectional view illustrating laser beam processing. FIG. 22(b) is a cross-sectional view illustrating masking member removal processing.

FIG. 23 is a cross-sectional view illustrating a state where the masking member is removed.

FIG. 24 is a cross-sectional view illustrating a radiation detector according to a modification example of the second embodiment.

DESCRIPTION OF EMBODIMENTS

Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the accompanying drawings. In the description of the drawings, the same elements are denoted by the same reference numerals with redundant description omitted.

The configuration of a radiation detector 1 according to the present embodiment will be described with reference to FIGS. 1 and 2 . As illustrated in FIGS. 1 and 2 , the radiation detector 1 includes a photoelectric conversion element array 7 (photodetection panel), a scintillator layer 8, a resin frame 9, a protective film 13 (scintillator protective film), and a coating resin 14 (coating resin). The photoelectric conversion element array 7 has a substrate 2, a light receiving portion 3, a signal line 4, a bonding pad 5, and a passivation film 6. The protective film 13 has a first organic film 10, an inorganic film 11 (metal film), and a second organic film 12.

The light receiving portion 3 includes a plurality of photoelectric conversion elements 3 a. The plurality of photoelectric conversion elements 3 a are two-dimensionally arranged in the rectangular region in the middle portion of the insulating substrate 2. The substrate 2 is, for example, a glass substrate. The photoelectric conversion element 3 a is configured by, for example, a photodiode (PD) or a thin film transistor (TFT) made of amorphous silicon. The photoelectric conversion element 3 a in each row or the photoelectric conversion element 3 a in each column included in the light receiving portion 3 is electrically connected to the bonding pad 5 for extracting a signal to an external circuit (not illustrated) by the signal line 4 for reading a signal.

A plurality of the bonding pads 5 are disposed at predetermined intervals along two adjacent sides of the outer edge of the substrate 2. The two adjacent sides are, for example, the upper side and the right side in FIG. 1 . The bonding pad 5 is electrically connected to the corresponding photoelectric conversion element 3 a via the signal line 4. The insulating passivation film 6 is formed on the photoelectric conversion element 3 a and the signal line 4. Silicon nitride, silicon oxide, or the like can be used for the passivation film 6. The bonding pad 5 is exposed for connection to the external circuit.

A scintillator 8 a has a columnar structure and converts X-rays, which are radiation, into light. The scintillator 8 a is laminated on the photoelectric conversion element array 7 so as to cover the light receiving portion 3. The scintillator layer 8 is formed by the scintillator 8 a. A plurality of the scintillators 8 a are laminated in the substantially rectangular region that includes the light receiving portion 3 in the photoelectric conversion element array 7. The substantially rectangular region is surrounded by the dashed line illustrated in FIG. 1 . Various materials can be used for the scintillator 8 a. For example, cesium iodide (CsI) doped with thallium (Tl) with satisfactory luminous efficiency can be used for scintillator 8 a.

A peripheral edge portion 8 b of the scintillator layer 8 has a gradient shape. In other words, the height of the peripheral edge portion 8 b gradually decreases toward the outside of the scintillator layer 8. In other words, as for the peripheral edge portion 8 b, the scintillator 8 a formed on the outside of the scintillator layer 8 is lower in height. The peripheral edge portion 8 b is a region where the light receiving portion 3 is not formed below. The region where the light receiving portion 3 is not formed is a region outside an effective screen. The peripheral edge portion 8 b is a region that has little effect on X-ray image generation. Accordingly, with the gradient-shaped peripheral edge portion 8 b, it is possible to limit the region on the scintillator layer 8 that is adversely affected by a laser beam during manufacturing. The gradient angle of the peripheral edge portion 8 b (angle θ) is defined. Defined first is a straight line connecting the height positions of the scintillators 8 a formed in the peripheral edge portion 8 b from the inside toward the outside of the scintillator layer 8. This straight line forms the angle θ with respect to the upper surface of the substrate 2. The angle θ is in the range of 20 degrees or more to 80 degrees or less.

The resin frame 9 is formed on the photoelectric conversion element array 7. The resin frame 9 passes between the scintillator layer 8 and the bonding pad 5 and surrounds the scintillator layer 8 when viewed in a lamination direction A of the scintillator layer 8. The corner portion of the resin frame 9 has an arc shape that is convex to the outside. The resin frame 9 is, for example, a silicone resin. It can be said that the shape of the corner portion of the resin frame 9 is a so-called R shape.

The middle portion of the resin frame 9 is higher than both edge portions of the resin frame 9. A height d1 of the resin frame 9 is lower than a height d of the scintillator layer 8. As a result, the resin frame 9 can be reduced in size. Further, the adverse effect of a laser beam on the scintillator layer 8 can be suppressed during manufacturing. The height d1 of the resin frame 9 is the distance from the position of the upper surface of the photoelectric conversion element array 7 to the position of the apex of the resin frame 9. The height d of the scintillator layer 8 is the maximum height of the scintillator 8 a included in the scintillator layer 8.

From the viewpoint of reducing the size of the radiation detector 1, it is preferable that the resin frame 9 is as small as possible. More specifically, the height d1 of the resin frame 9 is 100 μm or more to 300 μm or less. Further, a width d2 of the resin frame 9 is 700 μm or more to 1000 μm or less. The width d2 of the resin frame 9 is the width between an inner edge E1 of the resin frame 9 and an outer edge E2 of the resin frame 9. The inner edge E1 is an edge portion on the scintillator layer 8 side. The outer edge E2 is an edge portion on the bonding pad 5 side.

The distance from the inner edge E1 of the resin frame 9 to an outer edge E3 of the scintillator layer 8 is a first distance D1. The distance from the outer edge E2 of the resin frame 9 to an outer edge E4 of the photoelectric conversion element array 7 is a second distance D2. The first distance D1 is shorter than the second distance D2. The ratio of the second distance D2 to the first distance D1 is preferably 5 or more from the viewpoint of suppressing the adverse effect of a laser beam on the bonding pad 5 during manufacturing and ensuring the effective area of the scintillator layer 8. More specifically, the first distance D1 is preferably 1 mm or less. The second distance D2 is preferably 5 mm or more. This is because of the following reasons.

The effective area of the scintillator layer 8 can be maximized when no gap is provided between the outer edge E3 of the scintillator layer 8 and the inner edge E1 of the resin frame 9. However, it is conceivable that the scintillator layer 8 is adversely affected by a laser beam during manufacturing. In addition, a slight failure may arise in the process of forming the resin frame 9. The slight failure can be exemplified by, for example, forming the resin frame 9 on the scintillator layer 8. Considering these, it is preferable to set the first distance D1 in the range of 1 mm or less. The second distance D2 is set in the range of 5 mm or more. As a result, the adverse effect of a laser beam on the bonding pad 5 during manufacturing is taken into consideration, and thus a sufficient distance can be ensured between the resin frame 9 and the bonding pad 5.

The scintillator layer 8 is covered with the protective film 13. The protective film 13 has the first organic film 10, the inorganic film 11, and the second organic film 12. These films are laminated from the scintillator layer 8 side in this order. Each of the first organic film 10, the inorganic film 11, and the second organic film 12 transmits X-rays, which are radiation. In addition, the first organic film 10, the inorganic film 11, and the second organic film 12 block water vapor. Specifically, a polyparaxylylene resin, polyparachloroxylylene, or the like can be used for the first organic film 10 and the second organic film 12. The inorganic film 11 may be transparent, opaque, or reflective with respect to light. An oxide film such as silicon (Si), titanium (Ti), and chromium (Cr), a metal film such as gold, silver, and aluminum (Al), or the like can be used for the inorganic film 11. For example, the inorganic film 11 that uses a metal film reflecting light is capable of preventing leakage of fluorescence generated by the scintillator 8 a. As a result, the detection sensitivity of the radiation detector 1 is improved. Described in the present embodiment is an example in which aluminum (Al), which is easy to mold, is used as the inorganic film 11. Aluminum (Al) is easy to corrode in the air. However, the inorganic film 11 is sandwiched between the first organic film 10 and the second organic film 12. Accordingly, the inorganic film 11 that uses aluminum (Al) is protected from corrosion.

The protective film 13 is formed by, for example, a CVD method. Accordingly, immediately after the protective film 13 is formed, the protective film 13 covers the entire surface of the photoelectric conversion element array 7. Accordingly, in order to expose the bonding pad 5, the protective film 13 is cut at a position inside the bonding pad 5 of the photoelectric conversion element array 7. In the protective film 13, the part outside the cutting position is removed. As will be described later, the protective film 13 is cut by a laser beam in the vicinity of the outside of the middle portion of the resin frame 9 and an outer edge 13 a of the protective film 13 is fixed by the resin frame 9. As a result, it is possible to prevent the protective film 13 from peeling off from the outer edge 13 a. The carbon dioxide laser (CO₂ laser) or the like may be used in cutting the protective film 13. The protective film 13 can be cut with a single scan by means of the carbon dioxide laser. In other words, the protective film 13 can be cut in a short time. As a result, productivity is improved. In addition, an ultrashort pulse semiconductor laser on the order of nanoseconds or picoseconds or the like may be used in cutting the protective film 13. It should be noted that the adverse effects on the photoelectric conversion element array 7, the bonding pad 5, the scintillator layer 8, and so on can be exemplified by thermal damage when, for example, the carbon dioxide laser or an ultrashort pulse laser is used.

The outer edge 13 a of the protective film 13 is positioned on the resin frame 9. The outer edge 13 a is coated with the coating resin 14 together with the resin frame 9. The coating resin 14 is disposed along the resin frame 9. A resin that is satisfactorily adhesive with respect to the protective film 13 and the resin frame 9 may be used for the coating resin 14. For example, an acrylic adhesive or the like can be used for the coating resin 14. The same silicone resin as the resin frame 9 may be used for the coating resin 14. The same acrylic resin as the coating resin 14 may be used for the resin frame 9.

Next, the corner portions (corner parts) of the resin frame 9 and the protective film 13 will be described with reference to FIG. 3 . In FIG. 3 , the coating resin 14 is partially illustrated such that the states of the corner portions of the resin frame 9 and the protective film 13 are understood with ease.

As will be described in detail later, the protective film 13 on the resin frame 9 is irradiated with a laser beam in the process of manufacturing the radiation detector 1. As a result, the part of the protective film 13 irradiated with the laser beam is cut. The protective film 13 is very thin. Accordingly, a part of the resin frame 9 is also cut by the laser beam of the carbon dioxide laser. As a result, a groove 30 as a corresponding region is formed near the middle of the resin frame 9. The outer edge 13 a of the protective film 13 in the resin frame 9 is in a state of being processed by the laser beam. In addition, the groove 30 is also in a state of being processed by the laser beam. Here, a depth (height) d3 of the groove 30 is one-third or less of the height d1 of the resin frame 9. Suppressed as a result is the adverse effect of the laser beam on the photoelectric conversion element array 7 positioned below the resin frame 9.

As illustrated in FIG. 3 , the outer edge 13 a of the protective film 13 and the groove 30 processed by the laser beam have a substantially rectangular ring shape having an arcuate corner portion convex to the outside when viewed in the lamination direction A of the scintillator layer 8. The arcuate corner portion is illustrated in a region B illustrated in FIG. 3 . The outer edge 13 a of the protective film 13 and the surface of the groove 30 have a fine wave shape when viewed in the lamination direction A. The outer edge 13 a of the protective film 13 and the surface of the groove 30 are different in shape from a flat cut surface formed by an edged tool such as a cutter. The outer edge 13 a of the protective film 13 and the surface of the groove 30 have minute irregularities. As a result, the area of mutual contact between the outer edge 13 a of the protective film 13 and the coating resin 14 increases. Accordingly, the coating resin 14 is capable of adhering more firmly to the outer edge 13 a of the protective film 13. In addition, the area of mutual contact between the groove 30 and the coating resin 14 also increases. Accordingly, the coating resin 14 is also capable of adhering more firmly to the groove 30.

As illustrated in FIG. 1 , the groove 30 provided in the resin frame 9 includes three parts depending on the step of forming the groove 30. Specifically, the groove 30 includes a pre-irradiation portion Rs, a main irradiation portion Ra, and a post-irradiation portion Re. The pre-irradiation portion Rs and the post-irradiation portion Re overlap in an overlapping region 31. Details of the pre-irradiation portion Rs, the main irradiation portion Ra, and the post-irradiation portion Re will be described later.

The operation of the radiation detector 1 according to the present embodiment will be described. X-rays (radiation) incident from an incident surface reach the scintillator 8 a after transmission through the protective film 13. The X-rays are absorbed by the scintillator 8 a. The scintillator 8 a emits light proportional to the dose of the absorbed X-rays. The light that has been emitted and travels in the direction opposite to the incident direction of the X-rays is reflected by the inorganic film 11. As a result, almost all the light generated by the scintillator 8 a is incident on the photoelectric conversion element 3 a via the passivation film 6. The photoelectric conversion element 3 a generates an electric signal corresponding to the amount of the incident light by photoelectric conversion. The electric signal is accumulated over a certain period of time. The amount of the light corresponds to the dose of the incident X-rays. In other words, the electric signal accumulated in the photoelectric conversion element 3 a corresponds to the dose of the incident X-rays. Accordingly, an image signal corresponding to an X-ray image is obtained by means of this electric signal. The image signals accumulated in the photoelectric conversion element 3 a are sequentially read from the bonding pad 5 via the signal line 4. The read image signal is transferred to the outside. The transferred image signal is processed by a predetermined processing circuit. As a result, the X-ray image is displayed.

<Method for Manufacturing Radiation Detector>

Next, a method for manufacturing the radiation detector 1 according to the present embodiment will be described with reference to FIGS. 4 to 13 . First, the photoelectric conversion element array 7 is prepared as illustrated in FIG. 4(a) (Step S1). Subsequently, the scintillator layer 8 is formed (laminated) as illustrated in FIG. 4(b) (Step S2). Specifically, columnar crystals of cesium iodide (CsI) doped with thallium (Tl) are grown in the region that covers the light receiving portion 3 on the photoelectric conversion element array 7. An evaporation method or the like may be used for the growth of the columnar crystals. The thickness of the columnar crystals of cesium iodide (CsI) is, for example, approximately 600 μm.

Next, the resin frame 9 is formed on the photoelectric conversion element array 7 as illustrated in FIG. 5(a) (Step S3). Specifically, the resin frame 9 is formed so as to pass between the scintillator layer 8 and the bonding pad 5 and surround the scintillator layer 8 when viewed in the lamination direction A of the scintillator layer 8. More specifically, the resin frame 9 is formed at a position where the first distance D1 is 1 mm or less and the second distance D2 is 5 mm or more. An automatic X-Y coating device or the like can be used to form the resin frame 9. Hereinafter, what is obtained by forming the scintillator layer 8 and the resin frame 9 on the photoelectric conversion element array 7 will be simply referred to as “substrate” for convenience of description.

It should be noted that a masking member (see FIG. 20(a)) as illustrated in a second embodiment may be further disposed in addition to the resin frame 9 in Step S3. The masking member is a region outside the resin frame 9 and is disposed so as to cover the bonding pad 5. The masking member protects the surface of the bonding pad 5. When the masking member is disposed, the masking member is removed together with the protective film 13 in Step S6 of removing the outside part of the protective film 13, which will be described later.

Next, the first organic film 10 is formed as illustrated in FIG. 5(b) (Step S4 a). The cesium iodide (CsI) that forms the scintillator layer 8 is highly hygroscopic. Accordingly, with the scintillator layer 8 exposed, the scintillator layer 8 absorbs water vapor in the air. As a result, the scintillator layer 8 is dissolved. In this regard, the surface of the entire substrate is coated with polyparaxylylene by, for example, a CVD method. The thickness of the polyparaxylylene may be 5 μm or more and 25 μm or less.

Subsequently, the inorganic film 11 (metal film) is formed as illustrated in FIG. 6(a) (Step S4 b). Specifically, an aluminum film having a thickness of 0.2 μm is laminated by an evaporation method on the surface of the first organic film 10 on the incident surface side where radiation is incident. The incident surface where radiation is incident is the surface of the radiation detector 1 on the side where the scintillator layer 8 is formed. Subsequently, the second organic film 12 is formed as illustrated in FIG. 6(b) (Step S4 c). Specifically the surface of the entire substrate where the inorganic film 11 is formed is recoated with polyparaxylylene by a CVD method. The thickness of the polyparaxylylene may be 5 μm or more and 25 μm. The second organic film 12 prevents deterioration of the inorganic film 11 attributable to corrosion. The protective film 13 is formed as a result of Steps S4 a, S4 b, and S4 c. The part of the protective film 13 outside the substantially middle part of the resin frame 9 is removed through the subsequent treatment. The part of the protective film 13 outside the substantially middle part of the resin frame 9 covers the bonding pad 5. Accordingly, it is not necessary to form the first organic film 10 and the second organic film 12 on the side surface of the photoelectric conversion element array 7. In addition, it is not necessary to form the first organic film 10 and the second organic film 12 on the surface of the photoelectric conversion element array 7 on the side opposite to the surface where the scintillator layer 8 is laminated.

Subsequently, irradiation with a laser beam L is performed along the resin frame 9 as illustrated in FIG. 7 . As a result, the protective film 13 is cut (Step S5). Specifically, a laser beam head (not illustrated) performing irradiation with the laser beam L is moved with respect to a stage (not illustrated) where the entire substrate is placed with the protective film 13 formed on the surface of the entire substrate. As a result, scanning with the laser beam L is performed along the resin frame 9 in a one-stroke manner.

Hereinafter, Step S5 of cutting the protective film 13 will be described in more detail with reference to FIGS. 8, 9, 10, and 11 .

FIG. 8 is a time history of the energy that is received by an irradiated body in Step S5. In this specification, “irradiated body” is the protective film 13 and the resin frame 9. First, a cutting threshold (threshold energy) is defined. The cutting threshold is a value. The irradiated body is cut when irradiated with energy that is equal to or greater than this value. It should be noted that “cutting” in this specification means the formation of a void in the irradiated body and the void penetrates the irradiated body from the surface that is subject to laser beam irradiation to the surface that is the back with respect to the surface subject to the laser beam irradiation. Accordingly, the term of “cutting” does not pertain to a case where a bottom is provided without penetration from the surface subject to the laser beam irradiation to the back surface.

The cutting threshold is determined in accordance with the type of a material, the thickness of an object, and so on. The radiation detector 1 of the first embodiment includes the protective film 13 and the resin frame 9 as the irradiated body. Two cutting thresholds are defined in this case. Specifically, a cutting threshold Q1 related to the protective film 13 and a cutting threshold Q2 related to the resin frame 9 are defined. The cutting threshold Q2 related to the resin frame 9 is larger than the cutting threshold Q1 related to the protective film 13. In Step S5 of cutting the protective film 13, the protective film 13 is cut and the resin frame 9 is not cut. Then, in Step S5, the energy (Qs) of the laser beam to be emitted may be between the cutting threshold Q2 related to the resin frame 9 and the cutting threshold Q1 related to the protective film 13. Specifically, the energy (Qs) of the laser beam to be emitted may be smaller than the cutting threshold Q2 related to the resin frame 9 and larger than the cutting threshold Q1 related to the protective film 13.

The time history of the energy includes a period ts when the energy is increased, a period to when the energy is maintained, and a period to when the energy is decreased.

The period ts when the energy is increased corresponds to the period (Step S5 s) when the pre-irradiation portion Rs (see FIG. 1 ) is processed. The period ts includes a period ts1 and a period ts2. The period ts1 is a period for increasing the energy from a value (Q0) smaller than the cutting threshold Q1 to the cutting threshold Q1 of the protective film 13. The period ts2 is a period for increasing the energy from the cutting threshold Q1 of the protective film 13 to the energy (Qs). In the pre-irradiation portion Rs in the groove 30 formed in the period ts when the energy is increased, the depth of the pre-irradiation portion Rs gradually increases along the direction of laser beam scanning.

FIG. 9(a) illustrates the state of processing in the period ts. In the period ts1, the groove 30 does not reach the resin frame 9 since the energy is smaller than the cutting threshold Q1. Subsequently, the energy increases with the progress of laser beam scanning. When the energy subsequently reaches the cutting threshold Q1, the groove 30 penetrates the protective film 13. In other words, the groove 30 reaches the surface of the resin frame 9. Then, the groove 30 reaches a predetermined depth in the period ts2.

The period ta when the energy is maintained corresponds to the period (Step S5 a) when the main irradiation portion Ra (see FIG. 1 ) is processed. The period ta corresponds to a period when processing related to the main irradiation portion Ra illustrated in FIG. 1 is performed. Accordingly, the energy (Qs) in this period ta is larger than the cutting threshold Q1 of the protective film 13 and smaller than the cutting threshold Q2 of the resin frame 9. In the main irradiation portion Ra in the groove 30 formed in the period ta when the energy is maintained, the depth d3 of the main irradiation portion Ra is substantially constant along the direction of laser beam scanning.

FIGS. 9(b) and 9(c) illustrate the state of processing in the period ta. FIG. 9(b) illustrates a state immediately after the processing of the main irradiation portion Ra is started. FIG. 9(c) illustrates a state immediately before the processing of the main irradiation portion Ra ends. In this manner, setting is performed to the energy (Qs) at which the resin frame 9 can be cut to a predetermined depth. Then, the protective film 13 can be cut in a reliable manner, even if the thickness of the protective film 13 is increased or decreased to some extent, when the width of the increase or decrease is smaller than the width that corresponds to the depth.

The period te when the energy is decreased corresponds to the period (Step S5 e) when the post-irradiation portion Re (see FIG. 1 ) is processed. The period te includes a period te2 and a period te1. The period te2 is a period for decreasing the energy from the energy (Qs) to the cutting threshold Q1 of the protective film 13. The period te1 is a period for decreasing the energy from the cutting threshold Q1 of the protective film 13 to the value (Q0) smaller than the cutting threshold Q1. In the post-irradiation portion Re in the groove 30 formed in the period te when the energy is decreased, the depth of the post-irradiation portion Re gradually decreases along the direction of laser beam scanning.

FIGS. 10(a) and 10(b) illustrate the state of processing in the period te. The energy gradually decreases from the energy (Qs) in the period te. As illustrated in FIG. 10(a), the depth of the resin frame 9 in the groove 30 gradually decreases. Further, a part of the period te overlaps a part of the period ts in the direction of laser beam scanning. In other words, as illustrated in FIG. 10(b), the part already irradiated with a laser beam in the period ts is re-irradiated with a laser beam in the period te. In this manner, in the region on which laser beam irradiation is performed twice, the depth of the groove 30 gradually increases before the second irradiation. With respect to such a shape, in the second irradiation, the energy of the laser beam is controlled such that the depth of the formed groove 30 gradually decreases. Accordingly, a part P remaining in the first irradiation is removed by the second irradiation. As a result, the protective film 13 penetrates and the resin frame 9 is dug to a predetermined depth.

It should be noted that a depth W1 of the part formed in the periods ts and te may be equal to or different from a depth W2 of the part formed in the period ta. In other words, the depth W2 may be smaller than the depth W1. In addition, the depth W2 may be larger than the depth W1.

The history of the unit energy illustrated in FIG. 8 can be realized by one selected from several control variables. In addition, the history of the unit energy can be realized by combining a plurality of control variables.

Examples of the control variables include the movement speed of the laser beam head, the irradiation energy of the laser beam, and the focal position of the laser beam.

FIG. 11(a) is an example of the history of the movement speed of the laser beam head for realizing the history of the unit energy of FIG. 8 . In the period ts, the speed is reduced from V0 to Vs with the passage of time. In the period ta, the speed is maintained at Vs. In the period te, the speed is increased from Vs to V0 with the passage of time.

FIG. 11(b) is an example of the history of the irradiation energy of the laser beam for realizing the history of the unit energy of FIG. 8 . In the period ts, the energy is increased from Q0 to Qs with the passage of time. In the period ta, the energy is maintained at Qs. In the period te, the energy is reduced from Qs to Q0 with the passage of time.

FIG. 11(c) is an example of the history of the focal position of the laser beam for realizing the history of the unit energy of FIG. 8 . In the period ts, the focal position is brought closer to the surface of the irradiated body with the passage of time (P0 to Ps). In the period ta, the focal position is maintained on the surface of the irradiated body (Ps). In the period te, the focal position is moved away from the surface of the irradiated body with the passage of time (Ps to P0).

According to the above laser beam control mode, it is possible to reliably prevent the laser beam from penetrating the resin frame 9 as well as the protective film 13. In other words, the protective film 13 is cut in a reliable manner and the surface of the photoelectric conversion element array 7 provided with the resin frame 9 is not damaged by laser beam irradiation. Accordingly, the occurrence of a defective product is suppressed and productivity can be improved.

It should be noted that the following control may be performed in addition to the above control mode in carrying out Step S5.

The above control is on the premise that the initiation of the laser beam irradiation is simultaneous with the initiation of the laser beam head movement. By, for example, shifting the timing of the head movement initiation with respect to the timing of the irradiation initiation, it is possible to prevent the irradiated body from being irradiated with excessive energy.

For example, the operation at the irradiation initiation is as follows. First, the movement of the laser beam head is started (t0 in FIG. 12(a)). At this time, no laser beam irradiation is started (see a laser beam head 300 in FIG. 12(b)). The speed of the laser beam head increases with the passage of time (t0 to t1). Then, irradiation with the laser beam L is started when the speed of the laser beam head reaches a predetermined value (Va) (see ts in FIG. 12(a) and the laser beam head 300 in FIG. 12(b)). This predetermined value may be the steady speed (Vs). Alternatively, the value may be larger than a speed threshold (V1) and smaller than the steady speed (Vs). In other words, the timing (ts) when the laser beam irradiation is started is set to be preceded by the timing (t0) when the movement of the laser beam head is started. The timing of the irradiation initiation is delayed from the timing of the head movement initiation, and thus such control is called “delay control”.

In addition, when the laser beam irradiation is ended, the timing when the irradiation is stopped is set to precede the timing when the movement of the laser beam head is stopped. For example, the laser beam irradiation may be stopped when the speed of the laser beam head is the steady speed (Vs). In the period when the speed of the laser beam head is reduced, the laser beam irradiation may be stopped in a period when the speed allows irradiation with the unit energy that is below the cutting threshold Q1 of the resin frame 9. In addition, the energy per unit length decreases as the speed of the laser beam head increases. Accordingly, the laser beam irradiation may be stopped during an increase in laser beam head speed.

According to the above laser beam control mode, it is possible to more reliably prevent the laser beam from reaching the resin frame 9 as well as the protective film 13. In other words, the protective film 13 is cut in a reliable manner and the surface of the photoelectric conversion element array 7 provided with the resin frame 9 is not damaged by laser beam irradiation. Accordingly, the occurrence of a defective product is suppressed and productivity can be improved.

It should be noted that the above delay control is not premised on control based on the energy history illustrated in FIG. 8 . The delay control may be used alone.

The protective film 13 is cut by executing Step S5 described above.

Subsequently, as illustrated in FIG. 13(a), the part outside the portion of the protective film 13 cut by the laser beam L is removed. As a result, the bonding pad 5 is exposed (Step S6). The part outside the cut portion includes a part on the side opposite to the incident surface. Subsequently, as illustrated in FIG. 13(b), coating with an uncured resin material is performed along the resin frame 9 (Step S7). The uncured resin material is provided so as to cover the outer edge 13 a of the protective film 13 and the resin frame 9. The uncured resin material is, for example, an ultraviolet-curable acrylic resin or the like. Subsequently, the uncured resin material is irradiated with ultraviolet rays. As a result, the resin material is cured and the coating resin 14 is formed.

The protective film 13 comes into close contact with the photoelectric conversion element array 7 via the resin frame 9 even without the coating resin 14. However, by forming the coating resin 14, the protective film 13 including the first organic film 10 is sandwiched between the resin frame 9 and the coating resin 14. In other words, the protective film 13 is fixed. As a result, the close contact of the protective film 13 on the photoelectric conversion element array 7 is further improved. Accordingly, the scintillator 8 a is sealed by the protective film 13. As a result, moisture infiltration into the scintillator 8 a can be prevented in a reliable manner. In other words, it is possible to prevent a decline in element resolution attributable to the deterioration of the scintillator 8 a resulting from the moisture absorption of the scintillator 8 a.

In the first embodiment, the resin frame 9 is a panel protection portion. The panel protection portion may be configured by a plurality of members. For example, the panel protection portion may have the resin frame 9 and a masking member attached on the resin frame 9. According to this configuration, the panel protection portion configured by the resin frame 9 and the masking member is formed when laser beam irradiation is performed (Step S5). Accordingly, it is possible to ensure a considerable distance from the protective film 13 to the photoelectric conversion element array 7 with respect to the laser beam irradiation. As a result, the effect of the laser beam irradiation on the photoelectric conversion element array 7 can be suppressed more reliably.

<Action and Effect>

Hereinafter, the action and effect of the present embodiment will be described. In the problems described above, the laser beam irradiation mode may have a slight difference between preset content and actual operation. First, the mode is exemplified regarding this point.

The time at which the energy of the laser beam rises from zero (non-irradiation) to a predetermined level on the surface of the irradiated body when the laser beam irradiation is initiated (t1 in FIG. 14(a)) is much shorter than the time when the laser beam head reaches a predetermined movement speed from a movement speed of zero (t1 to t3 in FIG. 14(b)).

Then, the energy (Q3 to Qs) of the laser beam that the irradiated body receives per unit time (length) in the acceleration period (t1 to t3) from the zero movement speed to the predetermined laser beam head movement speed is different from the energy (Qs) of the laser beam that the irradiated body receives per unit time (length) in the steady period (t3 to t4) when the laser beam head moves at a predetermined speed. Specifically, the movement speed (Vs) of the laser beam head in the steady period (t3 to t4) exceeds the movement speed (0 to Vs) of the laser beam head in the acceleration period (t1 to t3). Accordingly, the energy (Q3 to Qs) of the laser beam that the irradiated body receives in the acceleration period (t1 to t3) exceeds the energy (Qs) of the laser beam that the irradiated body receives in the steady period (t3 to t4). Accordingly, assuming that the laser beam head is too slow with respect to the energy of the laser beam in the acceleration period (t1 to t3), the irradiated body may be irradiated with excessive energy. Assuming that this energy exceeds the energy (Q2) at which the resin frame 9 is cut, the photoelectric conversion element array 7 under the resin frame 9 may be damaged.

The radiation detector 1 includes the photoelectric conversion element array 7 having the light receiving portion 3 including the plurality of photoelectric conversion elements 3 a arranged one-dimensionally or two-dimensionally and the plurality of bonding pads 5 electrically connected to the photoelectric conversion elements 3 a and disposed outside the light receiving portion 3, the scintillator layer 8 laminated on the photoelectric conversion element array 7 so as to cover the light receiving portion 3 and converting radiation into light, the resin frame 9 formed on the photoelectric conversion element array 7 so as to pass between the scintillator layer 8 and the bonding pad 5 and surround the scintillator layer 8 apart from the scintillator layer 8 and the bonding pad 5 when viewed in the lamination direction A of the scintillator layer 8, and the protective film 13 covering the scintillator layer 8 and having the outer edge 13 a positioned on the resin frame 9. The groove 30 continuous with the outer edge 13 a of the protective film 13 is formed in the resin frame 9. The groove 30 includes the pre-irradiation portion Rs formed by performing scanning along the resin frame 9 while increasing the energy of the laser beam to a value larger than the cutting threshold Q1 from a value (Q0) smaller than the cutting threshold Q1 at which the protective film 13 can be cut, the main irradiation portion Ra formed by performing scanning along the resin frame 9 while maintaining the energy of the laser beam at a value (Qs) larger than the cutting threshold Q1, and the post-irradiation portion Re formed by performing scanning along the resin frame 9 while decreasing the energy of the laser beam from a value larger than the cutting threshold Q1 to a value (Q0) smaller than the cutting threshold Q1.

The groove 30 of the resin frame 9 of the radiation detector 1 is continuous with the outer edge 13 a of the protective film 13. Accordingly, the groove 30 is formed as the outer edge 13 a of the protective film 13 is formed by laser beam irradiation. When the groove is formed in the resin frame 9, the protective film 13 formed on the resin frame 9 is cut in a reliable manner. Further, in the pre-irradiation portion Rs, irradiation is started from the energy Q0 smaller than the cutting threshold Q1. According to such an irradiation mode, laser beam irradiation can be started with a margin with respect to the cutting threshold Q2 required for cutting the resin frame 9. Accordingly, even if energy exceeding a set value is supplied due to an unintended factor at the initiation of the laser beam irradiation, cutting of the resin frame 9 can be suppressed by the ensured margin. Likewise, in the post-irradiation portion Re, irradiation is stopped after the energy is decreased to Q0, which is smaller than the cutting threshold Q1. According to such an irradiation mode, laser beam irradiation can be stopped with a margin with respect to the cutting threshold Q2 required for cutting the resin frame 9. Accordingly, even if energy exceeding a set value is supplied due to an unintended factor when the laser beam irradiation is stopped, cutting of the resin frame 9 can be suppressed by the ensured margin. Accordingly, the occurrence of unintended cutting of the resin frame 9 can be suppressed.

The radiation detector 1 further includes the coating resin 14 covering the outer edge 13 a of the protective film 13. According to this configuration, the occurrence of peeling of the protective film 13 can be suppressed.

The coating resin 14 further covers the resin frame 9. The viscosity and the thixotropy of the coating resin 14 allow the coating resin 14 to stay on the resin frame 9 such that an edge portion 14 e of the surface where the coating resin 14 and the resin frame 9 come into contact with each other is formed on the resin frame 9. According to this configuration, the coating resin 14 reaches neither the surface of the photoelectric conversion element array 7 positioned outside the resin frame 9 nor the bonding pad 5. Accordingly, each of the surface of the photoelectric conversion element array 7 and the bonding pad 5 can be kept clean.

The middle portion of the resin frame 9 is higher than both edge portions of the resin frame 9. According to this configuration, the coating resin 14 is capable of covering the outer edge 13 a of the protective film 13 in a reliable manner.

The width of the resin frame 9 is 700 μm or more to 1000 μm or less. According to this configuration, the radiation detector 1 can be reduced in size.

The height of the resin frame 9 is 100 μm or more to 300 μm or less. According to this configuration, the radiation detector 1 can be reduced in size.

The method for manufacturing the radiation detector 1 has Step S2 of preparing the photoelectric conversion element array 7 having the light receiving portion 3 including the plurality of photoelectric conversion elements 3 a arranged one-dimensionally or two-dimensionally and the plurality of bonding pads 5 electrically connected to the photoelectric conversion elements 3 a and disposed outside the light receiving portion 3 and laminating the scintillator layer 8 converting radiation into light on the photoelectric conversion element array 7 so as to cover the light receiving portion 3, Step S3 of disposing the resin frame 9 on the photoelectric conversion element array 7 so as to surround the scintillator layer 8 when viewed in the lamination direction of the scintillator layer 8, Steps S4 a, S4 b, and S4 c of forming the protective film 13 so as to cover the entire surface of the photoelectric conversion element array 7 on the side where the scintillator layer 8 is laminated and the surface of the resin frame 9, Step S5 of cutting the protective film 13 by performing laser beam irradiation along the resin frame 9, and Step S6 of removing the outside part of the protective film 13. Step S5 of cutting the protective film 13 includes the pre-irradiation step S5 s of performing scanning along the resin frame 9 while increasing the energy of the laser beam to a value larger than the cutting threshold Q1 from a value smaller than the cutting threshold Q1 at which the protective film 13 can be cut, the main irradiation step S5 a of performing scanning along the resin frame 9 while maintaining the energy of the laser beam at a value larger than the cutting threshold Q1, and the post-irradiation step S5 e of performing scanning along the resin frame 9 while decreasing the energy of the laser beam from a value larger than the cutting threshold Q1 to a value smaller than the cutting threshold Q1.

In the method for manufacturing the radiation detector 1, the outer edge 13 a of the protective film 13 and the groove 30 of the resin frame 9 are formed in Step S5 of cutting the protective film 13. When the groove 30 is formed in the resin frame 9, the protective film 13 formed on the resin frame 9 is cut in a reliable manner. Further, the groove 30 includes the pre-irradiation step S5 s of forming the groove while increasing the energy and the post-irradiation step S5 e of forming the groove while decreasing the energy. According to the pre-irradiation portion Rs and the post-irradiation portion Re, the depth of the groove 30 does not excessively increase. Accordingly, the occurrence of unintended cutting of the resin frame 9 can be suppressed. As a result, it is possible to prevent the laser beam from penetrating the resin frame 9 as well as the protective film 13.

In other words, the protective film 13 is cut in a reliable manner and the surface of the photoelectric conversion element array 7 provided with the resin frame 9 is not damaged by laser beam irradiation. Accordingly, the occurrence of a defective product is suppressed and productivity can be improved.

In the method for manufacturing the radiation detector 1, the resin frame 9 is a panel protection portion. In Step S3 of disposing the resin frame 9, the resin frame 9 is disposed on the photoelectric conversion element array 7 so as to pass between the scintillator layer 8 and the bonding pad 5 and surround the scintillator layer 8 apart from the scintillator layer 8 and the bonding pad 5. According to this Step S3, the radiation detector 1 having the resin frame 9 can be manufactured.

The above has been described in detail based on the first embodiment of the present invention. However, the present invention is not limited to the first embodiment described above. The present invention can be modified in various ways without departing from the gist thereof.

The radiation detector of the present invention has been described in detail based on the first embodiment. However, the radiation detector of the present invention is not limited to the first embodiment. The present invention can be variously modified within the gist of the present invention. For example, the protective film 13 had a structure in which the inorganic film 11 was sandwiched between the first organic film 10 and the second organic film 12 made of polyparaxylylene. In other words, the material of the first organic film 10 was the same as the material of the second organic film 12. For example, the material of the first organic film 10 may be different from the material of the second organic film 12. In addition, the protective film 13 may lack the second organic film 12 when a material resistant to corrosion is used as the inorganic film 11. The light receiving portion 3 of the radiation detector 1 had the plurality of photoelectric conversion elements 3 a arranged two-dimensionally. The light receiving portion 3 may have the plurality of photoelectric conversion elements 3 a that are arranged one-dimensionally. The bonding pad 5 may be formed on two sides of the rectangular radiation detector 1. Further, the bonding pad 5 may be formed on three sides of the rectangular radiation detector 1. In addition, in the first embodiment, a method for performing laser processing by moving a laser beam head has been described. For example, laser beam irradiation may be performed while a stage where the radiation detector 1 is placed is moved.

Second Embodiment

A radiation detector 1A of the second embodiment and a method for manufacturing the radiation detector 1A will be described. In the radiation detector 1 of the first embodiment, the resin frame 9 is used as a panel protection portion. Specifically, the resin frame 9 is used as a member protecting the photoelectric conversion element array 7 from a laser beam in the step of cutting the protective film 13 in manufacturing the radiation detector 1. The radiation detector 1 includes the resin frame 9 as a component.

In the radiation detector 1A of the second embodiment, a masking member M1 (see FIG. 20 and so on) is used as a member protecting the photoelectric conversion element array 7 from a laser beam in cutting the protective film 13. The masking member M1 is removed after Step S15 of cutting a protective film 20. The radiation detector 1A does not include the masking member M1 as a component.

As illustrated in FIGS. 15 and 16 , the radiation detector 1A includes the photoelectric conversion element array 7, the scintillator layer 8, and the protective film 20. The photoelectric conversion element array 7 and the scintillator layer 8 are the same as those of the first embodiment. Accordingly, detailed description of the photoelectric conversion element array 7 and the scintillator layer 8 will be omitted. Hereinafter, the protective film 20 will be described in detail.

The protective film 20 has a main body portion 21 and an outer edge portion 22. The main body portion 21 covers the scintillator layer 8. The first organic film 10 in the main body portion 21 is provided on the scintillator layer 8. The spaces between the plurality of scintillators 8 a having the columnar structure are filled with the first organic film 10. The outer edge portion 22 is provided outside the main body portion 21. The outer edge portion 22 is continuous with the main body portion 21.

The outer edge portion 22 has a close contact portion 23 and an extending portion 24. The close contact portion 23 is in close contact with the photoelectric conversion element array 7 in a region K between the scintillator layer 8 and the bonding pad 5. For example, a part of the first organic film 10 that is on the scintillator layer 8 side in the close contact portion 23 has a surface in close contact with the photoelectric conversion element array 7. As a result, the close contact portion 23 comes into close contact with the photoelectric conversion element array 7. By enlarging the close contact surface, the close contact of the photoelectric conversion element array 7 with the close contact portion 23 is enhanced. The enlargement of the close contact surface is, in other words, increasing the sum of a length g1 and a length g2 of the close contact portion.

The close contact portion 23 has a first part 23 a and a second part 23 b. The first part 23 a is positioned on the main body portion 21 side. The first part 23 a has the first organic film 10, the inorganic film 11, and the second organic film 12. The first part 23 a is a three-layer structure. The second part 23 b is positioned on the side opposite to the main body portion 21 with the first part 23 a interposed therebetween. The second part 23 b has the first organic film 10 and the second organic film 12. The second part 23 b is a two-layer structure. An outer edge end 11 a of the inorganic film 11 is positioned inside an outer edge end 20 a of the protective film 20. In other words, the outer edge end 11 a of the inorganic film 11 is positioned on the scintillator layer 8 side. At the first part 23 a, the inorganic film 11 is sandwiched between an outer edge portion 10 b of the first organic film 10 and an outer edge portion 12 b of the second organic film 12. The second part 23 b is positioned outside an outer edge portion 11 b of the inorganic film 11. In other words, the second part 23 b is positioned closer to the bonding pad 5 side than the outer edge portion 11 b of the inorganic film 11. The outer edge portion 10 b of the first organic film 10 is joined to the outer edge portion 12 b of the second organic film 12 at the second part 23 b. The first organic film 10 and the second organic film 12 may be integrated when the first organic film 10 and the second organic film 12 are made of the same material. In the close contact portion 23, the outer edge portion 10 b of the first organic film 10 and the outer edge portion 12 b of the second organic film 12 wrap the outer edge portion 11 b of the inorganic film 11 in cooperation with each other.

The extending portion 24 has a two-layer structure made of the first organic film 10 and the second organic film 12. The extending portion 24 extends in a self-supporting state from the close contact portion 23 to the side opposite to the photoelectric conversion element array 7. The extending portion 24 is positioned on the side of the protective film 20 that is closest to the outer edge end 20 a. The outer edge end 20 a of the protective film 20 is configured by an outer edge end 10 a of the first organic film 10 and an outer edge end 12 a of the second organic film 12. The extending portion 24 has a rising portion 24 a and a piece portion 24 b. The rising portion 24 a extends in the normal direction of the surface of the photoelectric conversion element array 7 with the part of the close contact portion 23 that is on the side opposite to the main body portion 21 serving as a base end. Here, “self-supporting state” means a state where the rising portion 24 a is upright without being held or supported by any member. Examples of the member include resin. The base end part of the rising portion 24 a is connected to the close contact portion 23. The part of the rising portion 24 a other than the base end part is not in contact with any element of the radiation detector 1A.

The rising portion 24 a extends in a self-supporting state in the normal direction of the surface of the photoelectric conversion element array 7. In other words, the rising portion 24 a is upright from the photoelectric conversion element array 7. The extension direction of the rising portion 24 a is not limited thereto. The rising portion 24 a may extend in a self-supporting state along a direction intersecting with the direction that is parallel to the surface of the photoelectric conversion element array 7. For example, the rising portion 24 a may be inclined to the bonding pad 5 side with a state where the rising portion 24 a is upright from the photoelectric conversion element array 7 used as a reference. The rising portion 24 a may be inclined to the scintillator layer 8 side with a state where the rising portion 24 a is upright from the photoelectric conversion element array 7 used as a reference. In addition, the shape of the rising portion 24 a is not limited to a flat surface. The shape of the rising portion 24 a may be, for example, a curved surface.

The piece portion 24 b protrudes from the upper portion of the rising portion 24 a toward the bonding pad 5 side. The direction in which the piece portion 24 b protrudes is parallel to the surface of the photoelectric conversion element array 7. However, the direction in which the piece portion 24 b protrudes is not limited to the direction parallel to the surface of the photoelectric conversion element array 7. The direction in which the piece portion 24 b protrudes may be different from the direction in which the rising portion 24 a extends. For example, the piece portion 24 b may be inclined so as to gradually approach the photoelectric conversion element array 7 with a state where the piece portion 24 b is parallel to the surface of the photoelectric conversion element array 7 used as a reference. The piece portion 24 b may be inclined so as to be gradually separated from the photoelectric conversion element array 7. In addition, the shape of the piece portion 24 b is not limited to a flat surface. The shape of the piece portion 24 b may be, for example, a curved surface.

In FIG. 16 , the length g1 and the length g2 indicate the length of the close contact portion 23. Specifically, the length g1 indicates the length of the first part 23 a of the close contact portion 23. The length g2 indicates the length of the second part 23 b of the close contact portion 23. The sum of the length g1 and the length g2 is, for example, approximately 1000 μm. Alternatively, the sum of the length g1 and the length g2 is, for example, 1000 μm or less. A length g3 is the height of the rising portion 24 a. In other words, the length g3 is the height of the extending portion 24. The length g3 is, for example, 80 μm or more to 250 μm or less. A length g4 is the length of the piece portion 24 b of the extending portion 24. The length g4 is, for example, approximately 300 μm. Alternatively, the length g4 is, for example, 300 μm or less. A length g5 is the distance from the boundary between the close contact portion 23 and the extending portion 24 to the bonding pad 5. The length g5 is longer than the length g4. For example, the length g5 is longer than the length g4 by approximately tens of micrometers to hundreds of micrometers. According to this configuration, the extending portion 24 does not interfere with the bonding pad 5.

The external shape of the radiation detector 1A will be described. FIG. 17 is a perspective view schematically illustrating a corner part of the radiation detector 1A. FIG. 18 is a perspective view schematically illustrating the corner part of the radiation detector 1A viewed at an angle different from the angle in FIG. 17 . It should be noted that a cross section of the scintillator layer 8 is illustrated in FIG. 18 such that the scintillator layer 8 covered with the protective film 20 is visible. In FIG. 18 , the plurality of scintillators 8 a having the columnar structure are indicated by dashed lines. As is apparent from the drawings including FIGS. 17 and 18 , the outer edge portion 22 of the protective film 20 has the close contact portion 23 and the extending portion 24. The rising portion 24 a is inclined to the bonding pad 5 side. It should be noted that the piece portion 24 b may also be inclined to the bonding pad 5 side. In addition, the part where the rising portion 24 a and the piece portion 24 b are connected is not bent at a right angle. In other words, the part where the rising portion 24 a and the piece portion 24 b are connected may be bent smoothly.

<Action and Effect of Radiation Detector>

The action and effect of the radiation detector 1A will be described. In the radiation detector 1A, the outer edge portion 22 of the protective film 20 covering the scintillator layer 8 has the close contact portion 23 coining into close contact with the photoelectric conversion element array 7. With the close contact portion 23, it is possible to prevent moisture from entering toward the scintillator layer 8 from between the protective film 20 and the photoelectric conversion element array 7. Further, the outer edge portion 22 of the protective film 20 has the extending portion 24. The extending portion 24 extends in a self-supporting state along the direction opposite to the direction from the close contact portion 23 toward the photoelectric conversion element array 7. When the outer edge portion 22 of the protective film 20 does not have the extending portion 24, the outer edge end 20 a of the protective film 20 is included in the close contact portion 23. In that case, it becomes difficult to ensure a close contact between the part of the close contact portion 23 where the outer edge end 20 a of the protective film 20 is positioned and the photoelectric conversion element array 7 in particular. As a result, moisture is likely to intrude into the scintillator layer 8 from between the close contact portion 23 and the photoelectric conversion element array 7.

On the other hand, the outer edge portion 22 of the protective film 20 in the radiation detector 1A has the extending portion 24. The outer edge end 20 a of the protective film 20 is not included in the close contact portion 23. In other words, a close contact between the close contact portion 23 and the photoelectric conversion element array 7 can be ensured sufficiently. As a result, the moisture resistance of the scintillator layer 8 can be improved as compared with a case where the extending portion 24 is not provided. Accordingly, the moisture resistance of the scintillator layer 8 can be maintained even without holding the outer edge portion of the protective film 20 with a resin member (resin frame 9) as in the first embodiment. Further, the region K between the scintillator layer 8 and the bonding pad 5 can be narrowed since it is not necessary to provide the resin member supporting the outer edge portion of the protective film 20. For example, when the width of the resin frame 9 is approximately 900 μm, the region K can be reduced by the length that corresponds to the width of the resin frame 9. Accordingly, the radiation detector 1A is capable of ensuring the moisture resistance of the scintillator layer 8 and suppressing enlargement of the region K between the scintillator layer 8 and the bonding pad 5. In other words, the radiation detector 1A is capable of reducing the region K. As a result, the length of the signal line 4 electrically connecting the light receiving portion 3 to the bonding pad 5 can be reduced. Accordingly, electric signal transmission can be expedited. In addition, an increase in noise can be suppressed since the signal line 4 is short.

The protective film 20 has the inorganic film 11, the first organic film 10, and the second organic film 12. The first organic film 10 is disposed on the scintillator layer 8 side with respect to the inorganic film 11. The second organic film 12 is disposed on the side opposite to the scintillator layer 8 with respect to the inorganic film 11. By the protective film 20 including the inorganic film 11, it is possible to prevent the light generated in the scintillator layer 8 from leaking to the outside. In other words, it is possible to prevent the light generated in the scintillator layer 8 from leaking to a part other than the light receiving portion 3. As a result, the sensitivity of the radiation detector 1A is improved. The first organic film 10 and the second organic film 12 are provided on both sides of the inorganic film 11. According to this configuration, the first organic film 10 and the second organic film 12 are also capable of protecting the inorganic film 11.

The outer edge end 11 a of the inorganic film 11 is positioned inside the outer edge end 20 a of the protective film 20. The outer edge end 20 a of the protective film 20 is configured by the outer edge end 10 a of the first organic film 10 and the outer edge end 12 a of the second organic film 12. The outer edge portion 10 b of the first organic film 10 is joined to the outer edge portion 12 b of the second organic film 12 outside the outer edge end 11 a of the inorganic film 11. The outer edge portion 10 b of the first organic film 10 and the outer edge portion 12 b of the second organic film 12 cover the outer edge portion 11 b of the inorganic film 11. The outer edge portion 11 b of the inorganic film 11 is sealed by the outer edge portion 10 b of the first organic film 10 and the outer edge portion 12 b of the second organic film 12 even when, for example, the close contact between the inorganic film 11 and the first organic film 10 or the close contact between the inorganic film 11 and the second organic film 12 is not satisfactory. Accordingly, a close contact of the second organic film 12 with the first organic film 10 can be ensured.

The inorganic film 11 is a metal film made of aluminum or silver. Accordingly, the inorganic film 11 can be satisfactory in terms of light reflectivity.

The height of the extending portion 24 is 80 μm or more to 250 μm or less. Accordingly, the moisture resistance of the scintillator layer 8 can be ensured more reliably.

The extending portion 24 has the rising portion 24 a and the piece portion 24 b. The piece portion 24 b protrudes from the upper portion of the rising portion 24 a toward the bonding pad 5. The extending portion 24 has not only the rising portion 24 a but also the piece portion 24 b. Accordingly, the outer edge end 20 a of the protective film 20 can be at a sufficient distance from the close contact portion 23. As a result, a close contact of the photoelectric conversion element array 7 with the close contact portion 23 can be ensured more reliably. Even in this case, the length of the piece portion 24 b is, for example, approximately 300 μm. Alternatively, the length of the piece portion 24 b is, for example, 300 μm or less. Accordingly, the region K between the scintillator layer 8 and the bonding pad 5 can be reduced.

When a conductive member such as a wire is bonded to the bonding pad 5 in a wiring process or the like, foreign matter or the like may fly from the bonding part toward the scintillator layer 8 side. In that case, the extending portion 24 functions as a protective wall protecting the scintillator layer 8 from the foreign matter or the like. As a result, contamination of the scintillator layer 8 during bonding can be prevented.

The photoelectric conversion element array 7 may be expensive. It is conceivable to reuse the photoelectric conversion element array 7 when the radiation detector 1A is substandard in terms of quality or the like as a result of inspection in the manufacturing process. In that case, the scintillator layer 8 that is new is provided on the photoelectric conversion element array 7 after the scintillator layer 8 provided on the photoelectric conversion element array 7 is removed. Removal of the protective film 20 is required for that purpose. According to the radiation detector 1A of the present embodiment, the outer edge portion 22 of the protective film 20 has the extending portion 24. During peeling of the protective film 20 from the photoelectric conversion element array 7, for example, the extending portion 24 can be used as the starting point of the peeling, examples of which include gripping and pulling up the extending portion 24. Accordingly, with the extending portion 24, the protective film 20 can be removed with relative ease.

<Method for Manufacturing Radiation Detector>

Next, each step of the method for manufacturing the radiation detector 1A will be described with reference to FIGS. 19 to 23 . First, the photoelectric conversion element array 7 is prepared as illustrated in FIG. 19(a) (Step S11). Next, as illustrated in FIG. 19(b), the scintillator layer 8 is provided on the photoelectric conversion element array 7 so as to cover the light receiving portion 3 (Step S12).

Next, as illustrated in FIG. 20(a), the masking member M1 is provided on the photoelectric conversion element array 7 so as to cover the bonding pads 5 (Step S13). The masking member M1 is, for example, a UV-curable masking tape. Hereinafter, the UV-curable masking tape will be simply referred to as “UV tape”. The plurality of bonding pads 5 are disposed along the outer edge side of the substrate 2. Accordingly, first, the longitudinal direction of the UV tape is matched with the direction in which the bonding pads 5 are disposed. Next, the adhesive surface of the UV tape is attached to the photoelectric conversion element array 7 such that the UV tape covers the bonding pads 5. The thickness of the UV tape may be, for example, approximately 110 μm. In addition, the thickness of the UV tape may be 110 μm or less. A plurality of the UV tapes may be used in layers so that the thickness of the masking member M1 is adjusted.

The protective film 20 is provided on the photoelectric conversion element array 7 so as to cover the scintillator layer 8, the region K, and the masking member M1 (Step S14). Specifically, first, the first organic film 10 is formed as illustrated in FIG. 20(b) (Step S14 a). For example, the entire surface of the substrate 2 is coated with polyparaxylylene or the like by a CVD method. Next, the inorganic film 11 is formed on the first organic film 10 as illustrated in FIG. 21(a) (Step S14 b). For example, an aluminum film is laminated on the inorganic film 11 by an evaporation method. Here, the bonding pad 5 may not be covered with the inorganic film 11. In that case, the aluminum film may be evaporated after the bonding pad 5 is masked by means of a masking member M2. A UV tape or the like may be used for the masking member M2. Subsequently, the second organic film 12 is formed as illustrated in FIG. 21(b) (Step S14 c). For example, the entire surface of the substrate 2 is recoated with polyparaxylylene or the like by a CVD method.

Subsequently, as illustrated in FIG. 22(a), the protective film 20 is cut on the masking member M1 by irradiation with the laser beam L (Step S15). For example, a laser beam head (not illustrated) performing irradiation with the laser beam L is moved with respect to a stage (not illustrated) where the substrate 2 is placed. As a result, scanning with the laser beam L is performed along the edge portion of the masking member M1 that is on the scintillator layer 8 side.

The specific step may be the same as Step S5 of the first embodiment.

The masking member M1 is removed (Step S16). Specifically, the masking member M1 is removed after the adhesive force of the adhesive surface of the masking member M1, which is a UV tape, is reduced. First, irradiation with ultraviolet rays is performed toward the masking member M1 as illustrated in FIG. 22(b) (Step S16 a). The ultraviolet rays are transmitted through the protective film 20 and reach the masking member M1. The masking member M1 loses the adhesive force of the adhesive surface by being irradiated with the ultraviolet rays. Then, the masking member M1 is removed as illustrated in FIG. 23 (Step S16 b). The part of the cut protective film 20 covering the masking member M1 is removed together with the masking member M1. As a result, the bonding pad 5 is exposed.

<Action and Effect>

In the method for manufacturing the radiation detector 1A, the masking member M1 is a panel protection portion. In Step S13 of disposing the masking member M1, the masking member M1 is disposed on the photoelectric conversion element array 7 so as to cover the region K between the scintillator layer 8 and the bonding pad 5 and the bonding pad 5. In Step S14 of forming the protective film 20, the protective film 20 is formed on the entire surface of the photoelectric conversion element array 7 on the side where the scintillator layer 8 is laminated and the surface of the masking member M1. According to this Step S14, the radiation detector 1A without the resin frame 9 can be manufactured. In other words, the distance between the scintillator layer 8 and the bonding pad 5 can be reduced. Accordingly, the radiation detector 1A can be further reduced in size.

The method for manufacturing the radiation detector 1A further includes Step S16 b of removing the masking member M1 after Step S15 of cutting the protective film 20. According to these Steps S16 a and 516 b, the radiation detector 1A without the resin frame 9 can be manufactured in a suitable manner.

As illustrated in FIG. 24 , the method for manufacturing the radiation detector 1A further includes a step of forming a coating resin 14A covering the outer edge end 20 a of the protective film 20 after Step S16 a of removing the outside part of the protective film 20. According to this step, the occurrence of peeling of the outer edge end 20 a of the protective film 20 can be further suppressed.

According to the method for manufacturing the radiation detector 1A, the bonding pad 5 is covered with the masking member M1. In addition, the scintillator layer 8, the region between the scintillator layer 8 and the bonding pad 5, and the masking member M1 are covered with the protective film 20. As a result, the protective film 20 has the close contact portion 23 coining into close contact with the photoelectric conversion element array 7 in the region K between the scintillator layer 8 and the bonding pad 5. In addition, a step attributable to the thickness of the masking member M1 is generated between an end surface of the masking member M1 and the photoelectric conversion element array 7. The protective film 20 is formed along the step. As a result, the protective film 20 has the extending portion 24 extending from the close contact portion 23 to the side opposite to the photoelectric conversion element array 7. Further, irradiation with the laser beam L is performed along the edge portion of the masking member M1 that is on the scintillator layer 8 side. As a result, the protective film 20 is cut on the masking member M1. Then, the masking member M1 is removed. As a result, the bonding pad 5 is exposed. Further, the extending portion 24 is self-supporting without contact with the masking member M1. In addition, the extending portion 24 has the rising portion 24 a and the piece portion 24 b. The rising portion 24 a is formed along a step attributable to the edge of the masking member M1. The piece portion 24 b is formed between the rising portion 24 a and the edge portion of the masking member M1 irradiated with the laser.

The radiation detector 1A has the close contact portion 23 and the extending portion 24. The close contact portion 23 comes into close contact with the photoelectric conversion element array 7 in the region K between the scintillator layer 8 and the bonding pad 5. The extending portion 24 extends in a self-supporting state from the close contact portion 23 to the side opposite to the photoelectric conversion element array 7. Further, the extending portion 24 includes the rising portion 24 a and the piece portion 24 b. With these structures, the moisture resistance of the scintillator layer 8 can be maintained. Further, the region K between the scintillator layer 8 and the bonding pad 5 can be narrowed.

Here, it is also conceivable that the bonding pad 5 may be damaged as a result of irradiation with the laser beam L. However, in the method for manufacturing the radiation detector 1A, the bonding pad 5 is covered with the masking member M1 when the protective film 20 is cut. At this time, the masking member M1 serves as an absorption layer absorbing the laser beam L. Accordingly, it is possible to prevent the bonding pad 5 from being damaged by being irradiated with the laser beam L.

In the method for manufacturing the radiation detector 1A, the protective film 20 is cut by irradiation with the laser beam L (Step S15). According to Step S15, the close contact portion 23 and the extending portion 24 can be accurately molded in the outer edge portion 22 of the protective film 20. Even when the bonding pads 5 are disposed at predetermined intervals along a plurality of sides (for example, two to four sides) instead of one side of the outer edge of the substrate 2, scanning with the laser beam L may be performed for each side. Accordingly, the close contact portion 23 and the extending portion 24 can be easily molded in the outer edge portion 22.

Although the second embodiment has been described, the present invention is not limited to the second embodiment. For example, the outer edge end 11 a of the inorganic film 11 may configure the outer edge end 20 a of the protective film 20 together with the outer edge end 10 a of the first organic film 10 and the outer edge end 12 a of the second organic film 12.

The inorganic film 11 may be a resin film containing a white pigment. Examples of the white pigment include alumina, titanium oxide, zirconium oxide, and yttrium oxide. When a resin film containing a white pigment is the inorganic film 11, a metal film (for example, aluminum) and a third protective film (the same type of material as the first and second organic films) are further laminated in this order after the second organic film 12 is formed. Aluminum may be employed for the metal film. In addition, the same type of material as the first organic film may be employed for the third protective film. Further, the same type of material as the second organic film may be employed for the third protective film. According to these steps, moisture resistance comparable to that of a metallic reflective film can be obtained even with a resinous reflective film poor in moisture resistance. Further, the optical output that is obtained can be higher than that of a metallic reflective film. Even in this manner, the inorganic film 11 having light reflectivity can be realized.

REFERENCE SIGNS LIST

1, 1A: radiation detector, 2: substrate, 3: light receiving portion, 3 a: photoelectric conversion element, 4: signal line, 5: bonding pad, 6: passivation film, 7: photoelectric conversion element array, 8: scintillator layer, 8 a: scintillator, 8 b: peripheral edge portion, 9: resin frame, 10: first organic film, 11: inorganic film (metal film), 12: second organic film, 13: protective film, 13 a: outer edge of protective film 13, 14: coating resin, 30: groove, D1: first distance, D2: second distance, d, d1, d3: height, d2: width, E1: inner edge of resin frame 9, E2: outer edge of resin frame 9, E3: outer edge of scintillator layer 8, E4: outer edge of photoelectric conversion element array 7, M1: masking member. 

The invention claimed is:
 1. A radiation detector comprising: a photodetection panel having a light receiving portion including a plurality of photoelectric conversion elements arranged one-dimensionally or two-dimensionally and a plurality of bonding pads electrically connected to the photoelectric conversion elements and disposed outside the light receiving portion; a scintillator layer laminated on the photodetection panel so as to cover the light receiving portion and converting radiation into light; a panel protection portion formed on the photodetection panel so as to pass between the scintillator layer and the bonding pad and surround the scintillator layer apart from the scintillator layer and the bonding pad when viewed in a lamination direction of the scintillator layer; and a scintillator protective film covering the scintillator layer and having an outer edge positioned on the panel protection portion, wherein a groove continuous with the outer edge of the scintillator protective film is formed in the panel protection portion, and the groove includes: a pre-irradiation portion formed by performing scanning along the panel protection portion while increasing energy of a laser beam to a value larger than threshold energy from a value smaller than the threshold energy at which the scintillator protective film can be cut; a main irradiation portion formed by performing scanning along the panel protection portion while maintaining the energy of the laser beam at a value larger than the threshold energy; and a post-irradiation portion formed by performing scanning along the panel protection portion while decreasing the energy of the laser beam from a value larger than the threshold energy to a value smaller than the threshold energy.
 2. The radiation detector according to claim 1, further comprising a coating resin covering the outer edge of the scintillator protective film.
 3. The radiation detector according to claim 2, wherein the coating resin further covers the panel protection portion, and the coating resin has a material property allowing the coating resin to stay on the panel protection portion such that an edge portion of a contact surface between the coating resin and the panel protection portion is formed on the panel protection portion.
 4. The radiation detector according to claim 2, wherein a middle portion of the panel protection portion is higher than edge portions of the panel protection portion.
 5. The radiation detector according to claim 1, wherein a width of the panel protection portion is 700 μm or more to 1000 μm or less.
 6. The radiation detector according to claim 1, wherein a height of the panel protection portion is 100 μm or more to 300 μm or less.
 7. A radiation detector manufacturing method comprising: a step of preparing a photodetection panel having a light receiving portion including a plurality of photoelectric conversion elements arranged one-dimensionally or two-dimensionally and a plurality of bonding pads electrically connected to the photoelectric conversion elements and disposed outside the light receiving portion and laminating a scintillator layer converting radiation into light on the photodetection panel so as to cover the light receiving portion; a step of disposing a panel protection portion on the photodetection panel so as to surround the scintillator layer when viewed in a lamination direction of the scintillator layer; a step of forming a scintillator protective film so as to cover an entire surface of the photodetection panel on a side where the scintillator layer is laminated and a surface of the panel protection portion; a step of cutting the scintillator protective film by performing irradiation with a laser beam along the panel protection portion; and a step of removing an outside part of the scintillator protective film, wherein the step of cutting the scintillator protective film includes: a pre-irradiation step of performing scanning along the panel protection portion while increasing energy of the laser beam to a value larger than threshold energy from a value smaller than the threshold energy at which the scintillator protective film can be cut; a main irradiation step of performing scanning along the panel protection portion while maintaining the energy of the laser beam at a value larger than the threshold energy; and a post-irradiation step of performing scanning along the panel protection portion while decreasing the energy of the laser beam from a value larger than the threshold energy to a value smaller than the threshold energy.
 8. The radiation detector manufacturing method according to claim 7, wherein the panel protection portion includes a resin frame, and in the step of disposing the panel protection portion, the resin frame is disposed on the photodetection panel so as to pass between the scintillator layer and the bonding pad and surround the scintillator layer apart from the scintillator layer and the bonding pad.
 9. The radiation detector manufacturing method according to claim 8, wherein the panel protection portion further includes a masking member, and in the step of disposing the panel protection portion, the masking member is further disposed on the photodetection panel so as to cover the bonding pad.
 10. The radiation detector manufacturing method according to claim 7, wherein the panel protection portion includes a masking member, in the step of disposing the panel protection portion, the masking member is disposed on the photodetection panel so as to cover a region between the scintillator layer and the bonding pad and the bonding pad, and in the step of forming the scintillator protective film, the scintillator protective film is formed on the entire surface of the photodetection panel on the side where the scintillator layer is laminated and a surface of the masking member.
 11. The radiation detector manufacturing method according to claim 10, further comprising a step of removing the masking member after the step of cutting the scintillator protective film.
 12. The radiation detector manufacturing method according to claim 10, further comprising a step of forming a coating resin covering an outer edge of the scintillator protective film after the step of removing the outside part of the scintillator protective film. 